Development of risk-based nanomaterial groups for occupational exposure control

Kuempel, Eileen D.; Castranova, Vince; Geraci, Charles L.; Schulte, Paul A.

doi:10.1007/s11051-012-1029-8

Cited by 103 publications

(103 citation statements)

References 61 publications

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“…Physico-chemical properties of nanomaterials that have been recognized to influence their inhalability, deposition efficiency, and toxicology are their airborne and hydrodynamic size, size distribution, shape (and aspect ratio), their state of agglomeration, surface properties and functionalization (surface area, porosity, charge, reactivity, chemistry/ coatings, contaminants), as well as solubility and crystallinity (Kuempel et al, 2012;Nel et al, 2013a;Oberdörster, 2009;Oberdörster et al, 1994;Rodriguez-Yanez et al, 2013;Zhu et al, 2013). Also in in vitro cytotoxicity assays, particle size, surface chemistry and coating, as well as chemical composition have been recognized as key determinants of nanoparticle adverse effects (Feltis et al, 2012;Horev-Azaria et al, 2011;Kroll et al, 2011).…”

Section: Particle Characteristics Influencing Particle Effectsmentioning

confidence: 99%

“…Also in vivo, ZnO NM effects are reported being caused by dissolved ions (Kuempel et al, 2012), as recorded by increased LDH levels in the bronchoalveolar fluid (BALF; Kao et al, 2012). Klein et al (2012) found short-term inhalation exposure to 2.5 and 12.5 mg/m 3 Z-COTE® HP1 to increase inflammatory parameters in the BALF in a concentrationdependent manner.…”

Section: Comparison Of Nm Effects In the Pclus Test System To In Vivomentioning

confidence: 99%

“…For TiO 2 NMs, dose metrics related to adverse effects are surface area, volume, mass or number (by particle size fraction), with the dose-response relationship possibly being non-linear at low doses (Kuempel et al, 2012). In a rat short-term inhalation study (STIS; 5-day exposure period, 6-hour exposure/day), both nanoscaled (70% anatase/ 30% rutile, 20-30 nm, TEM; test substance concentration 100 mg/m 3 ) and pigmentary (non-nano) TiO 2 (200 nm, DLS; test substance concentration 250 mg/m 3 ) induced reversible mild neutrophilic inflammation and activation of macrophages in the lung (van Ravenzwaay et al, 2009).…”

Section: Comparison Of Nm Effects In the Pclus Test System To In Vivomentioning

confidence: 99%

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Applicability of rat precision-cut lung slices in evaluating nanomaterial cytotoxicity, apoptosis, oxidative stress, and inflammation

Sauer¹,

Vogel²,

Aumann³

et al. 2014

Toxicology and Applied Pharmacology

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The applicability of rat precision-cut lung slices (PCLuS) in detecting nanomaterial (NM) toxicity to the respiratory tract was investigated evaluating sixteen OECD reference NMs (TiO₂, ZnO, CeO₂, SiO₂, Ag, multi-walled carbon nanotubes (MWCNTs)). Upon 24-hour test substance exposure, the PCLuS system was able to detect early events of NM toxicity: total protein, reduction in mitochondrial activity, caspase-3/-7 activation, glutathione depletion/increase, cytokine induction, and histopathological evaluation. Ion shedding NMS (ZnO and Ag) induced severe tissue destruction detected by the loss of total protein. Two anatase TiO₂ NMs, CeO₂ NMs, and two MWCNT caused significant (determined by trend analysis) cytotoxicity in the WST-1 assay. At non-cytotoxic concentrations, different TiO₂ NMs and one MWCNT increased GSH levels, presumably a defense response to reactive oxygen species, and these substances further induced a variety of cytokines. One of the SiO₂ NMs increased caspase-3/-7 activities at non-cytotoxic levels, and one rutile TiO₂ only induced cytokines. Investigating these effects is, however, not sufficient to predict apical effects found in vivo. Reproducibility of test substance measurements was not fully satisfactory, especially in the GSH and cytokine assays. Effects were frequently observed in negative controls pointing to tissue slice vulnerability even though prepared and handled with utmost care. Comparisons of the effects observed in the PCLuS to in vivo effects reveal some concordances for the metal oxide NMs, but less so for the MWCNT. The highest effective dosages, however, exceeded those reported for rat short-term inhalation studies. To become applicable for NM testing, the PCLuS system requires test protocol optimization.

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Section: Particle Characteristics Influencing Particle Effectsmentioning

confidence: 99%

Section: Comparison Of Nm Effects In the Pclus Test System To In Vivomentioning

confidence: 99%

Section: Comparison Of Nm Effects In the Pclus Test System To In Vivomentioning

confidence: 99%

See 1 more Smart Citation

Applicability of rat precision-cut lung slices in evaluating nanomaterial cytotoxicity, apoptosis, oxidative stress, and inflammation

Sauer¹,

Vogel²,

Aumann³

et al. 2014

Toxicology and Applied Pharmacology

View full text Add to dashboard Cite

show abstract

“…determining the health risk). The banding strategies developed for nanomaterials have been recently reviewed [20], and approaches to link quantitative risk assessment with exposure control banding schemes (for categorical decision-making and validation) have been described [21].…”

Section: Societal Level Risk Managementmentioning

confidence: 99%

“…It is unlikely that it will be possible to assess toxicologically (using animal studies) all the ENMs in, or entering, commerce [21,36,37]. Therefore, it may be necessary to screen materials individually or as categories and assign them to hazard and control categories (based on physical-chemical parameters).…”

Section: Need To Develop Categorical Oelsmentioning

confidence: 99%

Overview of Risk Management for Engineered Nanomaterials

Schulte

Geraci

Hodson

et al. 2013

J. Phys.: Conf. Ser.

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Occupational exposure to engineered nanomaterials (ENMs) is considered a new and challenging occurrence. Preliminary information from laboratory studies indicates that workers exposed to some kinds of ENMs could be at risk of adverse health effects. To protect the nanomaterial workforce, a precautionary risk management approach is warranted and given the newness of ENMs and emergence of nanotechnology, a naturalistic view of risk management is useful. Employers have the primary responsibility for providing a safe and healthy workplace. This is achieved by identifying and managing risks which include recognition of hazards, assessing exposures, characterizing actual risk, and implementing measures to control those risks. Following traditional risk management models for nanomaterials is challenging because of uncertainties about the nature of hazards, issues in exposure assessment, questions about appropriate control methods, and lack of occupational exposure limits (OELs) or nano-specific regulations. In the absence of OELs specific for nanomaterials, a precautionary approach has been recommended in many countries. The precautionary approach entails minimizing exposures by using engineering controls and personal protective equipment (PPE). Generally, risk management utilizes the hierarchy of controls. Ideally, risk management for nanomaterials should be part of an enterprisewide risk management program or system and this should include both risk control and a medical surveillance program that assesses the frequency of adverse effects among groups of workers exposed to nanomaterials. In some cases, the medical surveillance could include medical screening of individual workers to detect early signs of work-related illnesses. All medical surveillance should be used to assess the effectiveness of risk management; however, medical surveillance should be considered as a second line of defense to ensure that implemented risk management practices are effective.

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Control Banding: Background, Evolution, and Application

Zalk

West

Nelson³

2021

Patty's Industrial Hygiene

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Control banding (CB) strategies offer a solution for controlling worker exposures to constituents that are found in the workplace in the absence of firm toxicological and exposure data. The CB approach is now recognized in developed countries and economically developing countries and is considered as the most practical approach for the prevention of work‐related risks. As CB strategies are more prevalent in practice, the need for newer professionals to understand their strengths and weaknesses becomes an essential component of their ongoing education.

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Development of risk-based nanomaterial groups for occupational exposure control

Cited by 103 publications

References 61 publications

Applicability of rat precision-cut lung slices in evaluating nanomaterial cytotoxicity, apoptosis, oxidative stress, and inflammation

Applicability of rat precision-cut lung slices in evaluating nanomaterial cytotoxicity, apoptosis, oxidative stress, and inflammation

Overview of Risk Management for Engineered Nanomaterials

Control Banding: Background, Evolution, and Application

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